KR101041224B1 - Automatic controll system for saving energy and safety - Google Patents

Abstract

PURPOSE: An automatic control system for saving energy with safety is provided to block power supply to electric devices which are necessary the least if power exceeds reference peak power, thereby saving energy. CONSTITUTION: Power facilities(F11~F13) distribute power supplied to a building to each device using electricity. Air conditioning facilities(F21~F23) adjust the temperature, humidity, and ventilation in a building. Lighting facilities(F31~F33) control the illumination in the building. A building facility comprises an anti-disaster facility. A remote control panel(C.C) is placed in the power facilities, the air conditioning facilities, the lighting facilities, and the anti-disaster facility.

Description

Automatic controll system for saving energy and safety

The present invention manages a variety of building equipment, such as power equipment, lighting equipment, air conditioning equipment, sanitary equipment, disaster prevention equipment installed in large buildings such as factories, buildings, apartments, etc., energy saving, pleasant environment, disaster prevention, rapid maintenance, etc. The present invention relates to an automatic control system for a building facility to enable the above-mentioned. More specifically, the electric power supply system for the electric equipment installed in the building exceeds the reference peak power. Energy-saving automatic control system that saves energy costs and prevents the expansion of disasters and protects the system by shutting down the on-site equipment that can cause secondary damage in the event of a disaster such as fire or earthquake It is about.

As buildings are becoming larger and more functional, various facilities such as air conditioning, sanitation, electric power, lighting, crime prevention, disaster prevention, and water treatment are complicatedly installed, and various building equipment automatic control systems are proposed to detect and control these facilities. It is becoming.

The building equipment automatic control system controls various building equipments installed in the building, the central control device that manages and controls the system as a whole, controls the operation of the field devices, collects, analyzes and responds to the information of the field devices, and analyzes them. It consists of a remote control panel that transmits information to the central control unit.

The remote control panel controls the field devices under the control of the central control unit, but can be operated independently to control the operation of the field devices independently.

Conventional technologies related to the automatic control of building equipment include Patent No. 0963161, "Smart Energy Management System and Method of Buildings," Patent No. 057672, "Intelligent Control Information for Optimal Management and Energy Saving of Office Building Equipment." This has been disclosed variously.

By the way, the automatic control of the building equipment according to the related art appropriately restricts the power consumption in the corresponding building, and prevents the power supply from falling down due to excessive power consumption and saves energy. In case of disasters such as floods, it is weak to minimize disasters and damages and to protect the system.

Therefore, the automatic building equipment control system according to the prior art needs to enhance this function.

And, as described above, the remote control panel constituting the automatic control system for the building equipment needs to be able to independently control and operate the field devices separately from the central control apparatus.

Thus, a driving power supply unit for converting power input from the outside into the driving power required for operation is provided. The external power often includes surge or overvoltage, and the surge or overvoltage damages the driving power supply and the remote control panel. And cause the remote control panel to malfunction.

The remote control panel collects various types of information from the field devices, analyzes them, and collects and analyzes the stored information together with the field devices.

However, when the power supply is suddenly cut off due to an accident such as a power failure, stored information is lost.

In addition, the remote control panel communicates with the central control unit by wire. When a communication line for wired communication occurs, transmission and reception of data is blocked, making it difficult to control building equipment.

As such, the remote control panel protects the building equipment stably and continuously by blocking surges and overvoltages from the external input power, and maintains its own operation for a certain time even when the external power supply is cut off due to power failure. It is possible to enable wireless communication of data with the central control unit even if a wire communication fails.

However, the prior art does not have such means separately.

The present invention has been made by solving the problems and necessity of the automatic control of the building equipment according to the prior art as described above, in the event of a disaster such as fire or earthquake in the building and in the case of excessive power consumption in the case of excessive power consumption measures by stability It is an object of the present invention to provide an energy-saving automatic control system with high stability and low energy cost.

The remote control panel (which may also include a central control unit) connects an overvoltage breaker to the input side of the driving power supply to prevent damage or malfunction of the driving power supply and the remote control panel, and includes an uninterruptible power supply (UPS) to provide external power. Even if the supply is interrupted, various information is stably preserved, so the recovery operation of the remote control panel can be resumed conveniently and quickly, and if the wire communication with the central control device fails, the data can be transmitted and received by wireless communication immediately. It is an object of the present invention to provide an energy-saving automatic control system with stability that enables stable control.

Energy-saving automatic control system having a stability according to the present invention for achieving the above object

Power equipment including distribution panel, distribution panel, electricity meter, and distributing electric power to the building,

Including heater and air conditioner, temperature sensor, humidifier and humidity sensor, ventilator and dust sensor, air conditioning equipment to control temperature, humidity and ventilation in the building,

It includes a luminaire, an illuminance sensor, an entrance detection sensor, lighting equipment for controlling lighting in a building,

Building equipment including fire detectors, fire hydrants, earthquake detection sensors, and disaster prevention facilities for preventing disasters in buildings;

A remote control panel provided in each of the power equipment, the air conditioning equipment, the lighting equipment, and the disaster prevention equipment to control field devices constituting them;

In the building equipment automatic control system comprising a computer, a monitor and a database, the central control unit for communicating with the remote control panel, the monitoring and management of the situation of the building facilities;

The remote control panel

Communication unit for communicating with the central control device;

An input / output unit for inputting / outputting data with a field device;

An operation unit including a keypad and a display unit for a user operation;

A memory for storing input / output information with an operating program;

The communication unit, the input / output unit, the operation unit and the memory are connected to control them, and a microcomputer for analyzing the data of the field apparatus input from the input / output unit;

The central control device

Analyzing the information transmitted from the remote control panel provided in the power equipment, if the power consumption of the building exceeds the reference peak power, the power supply to the electrical devices are cut off according to the priority stored in the database to save energy Reduce costs,

Analyze the information transmitted from the remote control panel provided in the disaster prevention equipment, and in the event of a fire, stop the operation of the building equipment (except the disaster prevention equipment) installed in the fire occurrence zone, and register it in the database if an earthquake occurs. It is characterized by increasing the stability by stopping the operation of the field device of high pressure or high temperature stored large risk factors.

And further comprising a solar generator, a storage battery, the solar power generation equipment for supplying power storage power to the switchgear of the power equipment;

The remote control panel

Enclosure to protect the components built-in,

Outside air inlets and bottom air outlets respectively formed in the lower and upper parts of the enclosure,

A temperature sensor and a humidity sensor mounted inside the enclosure;

Further comprising an intake fan and an exhaust fan provided inside the enclosure adjacent to the inlet and outlet,

The microcomputer drives the intake fan and the exhaust pin according to the signals sensed by the temperature sensor and the humidity sensor, and maintains a constant temperature and humidity inside the enclosure to increase stability.

The remote control panel

A driving power supply unit converting power input through a power line into driving power and supplying the power to the microcomputer;

An overvoltage circuit breaker connected to an input side of the driving power supply and blocking a surge and an overvoltage of a power input through a power line;

The overvoltage breaker

Surge interruption part which absorbs the surge of the input power supply, and blocks it,

A noise removing unit for removing noise of the power supply passing through the surge blocking unit;

A switching unit which is provided at an output terminal and supplies or cuts off the power passing through the noise removing unit by an on / off switching operation to the driving power supply unit;

A detector for detecting the intensity of the power output from the noise removing unit;

A control unit which receives the detection signal of the detection unit and controls an on / off switching operation of the switching unit to cut off the overvoltage;

A counter electromotive force blocking unit to block back electromotive force introduced from the driving power supply unit through the switching unit;

And a starting power supply unit rectifying and smoothing the output power of the noise removing unit to supply the starting power to the switching unit.

The communication unit of the remote control panel and the wired communication unit for communicating with the central control unit by wire;

In the case of a failure in the communication of the wired communication unit is made to include a wireless communication unit for communicating wirelessly,

The wireless communication unit

An antenna for wirelessly transmitting and receiving data to and from the central control apparatus;

A low pass filter for filtering received data and transmitted data of the antenna;

A first impedance matching unit and a first impedance matching unit connected to the front and rear of the first band pass filter and the second band pass filter for filtering the received data passing through the low pass filter, respectively; A reception data processing unit including a second impedance matching unit, a noise amplifying unit amplifying low frequency band noise of the output received data of the first impedance matching unit, and inputting the low frequency band noise to the second impedance matching unit;

A power amplifier for amplifying the transmission data, a third impedance matching unit connected to the front and rear of the power amplifier, and an all-pass filter for removing noise of the output data of the third impedance matching unit and filtering the output data into the low pass filter; A transmission data processing unit,

A phase synchronization unit for synchronizing the signal phase of the reception data inputted from the reception data processing unit with the transmission data outputted to the transmission data processing unit;

A transmission / reception selection switch connecting the low pass filter to the reception data processor or the transmission data processor;

A power supply unit including a driving power unit for generating a driving power required for driving the communication unit by converting the external input power into a constant voltage, and a communication power unit for generating a communication power for wireless communication by constant voltage output power of the driving power unit;

And a CPU for relaying transmission and reception of the reception data and the transmission data between the phase synchronization unit and the microcomputer and controlling the communication unit.

The energy-saving automatic control system with stability according to the present invention having such a configuration provides power to electric devices of low importance (necessity) immediately when the power consumption in the building exceeds the reference peak power before exceeding the maximum allowable power. By cutting off the supply, it minimizes inconvenience and reduces energy costs, and prevents damage caused by sudden power down beyond the maximum allowable power,

In the event of a disaster, the secondary equipment caused by the disaster is prevented by stopping the operation of the on-site equipment, which may have caused problems due to the disaster, and the system may be affected by the adverse effects of the problem on the on-site equipment. Problems can be prevented from occurring.

In addition, the remote control panel, which is under the control of the central control unit, can independently manage and control the field devices so that the overvoltage circuit breaker cuts the surge or overvoltage of the external power input through the power line, thereby preventing the surge from the surge or overvoltage. Protect various connected devices (microcom, communication unit, operation unit, etc.), prevent malfunction

The UPS including the battery and the charging module supplies power in the event of a power failure so that the information stored in the memory is not damaged. When the recovery is resumed, it can be operated immediately when external power is supplied.

If a failure occurs in the central control device and the wired communication, it is possible to prevent the difficult problem in the control management of the building equipment by transmitting and receiving data by wireless communication.

1 is a conceptual diagram of an energy saving automatic control system having stability according to the present invention.
2 is a schematic block diagram of an energy saving automatic control system having stability according to the present invention;
3 is a schematic front, side and inner view of a remote control panel according to the present invention;
4 is a circuit diagram of an overvoltage breaker according to the present invention.
5, a, b, and c are circuit diagrams of a wireless communication unit according to the present invention;
Figure 6 is a block diagram of a UPS charging module according to the present invention.

Hereinafter, the energy saving type automatic control system having stability according to the present invention will be described in more detail with reference to FIGS. 1 to 6.

First, as shown in FIG. 1, the energy saving type automatic control system having stability according to the present invention includes various building facilities F, a remote control panel P provided in each building facility F, and a remote control panel ( It includes a central control unit (CC) that communicates with P) and controls and manages the system as a whole.

The building equipment (F) is a power equipment (F11, 12, 13), air conditioning equipment (F21, 22, 23), lighting equipment (F31, 32, 33), disaster prevention equipment (F41, 42), solar power generation equipment ( F51, 52), and may further include various kinds of building equipment such as heating equipment, security equipment, communication equipment.

The power equipments F11, 12, and 13 are facilities for distributing power supplied by a power company to electric devices that require it. It includes a distribution panel for distributing electricity to devices using a line, and an electricity meter for measuring the amount of power supplied by the utility company and the amount of power used by the devices.

The air conditioning equipment (F21, 22, 23) is to adjust the temperature and humidity in the building, and to remove the fine dust in the air to make the environment inside the building comfortable, heaters and air conditioners for temperature control, and their Temperature sensor to sense temperature to determine whether it is running, humidifier to control humidity, humidity sensor to sense humidity to determine whether the humidifier is running, and ventilator to discharge fine dust in the air to the outside And a dust sensor that detects the density of the fine dust to determine whether the fan is operating.

The lighting equipment F31, 32, 33 is a facility for illuminating the interior of the building, and includes a lamp, a timer for determining the lighting timing of the lamp, an illuminance sensor, an entrance sensor, and the like.

The disaster prevention facilities (F41, 42) is a facility for detecting and preventing the occurrence of a disaster in a building, and includes a fire detection, fire hydrant, flue smoke, evacuation induction, earthquake detection sensor, eccentricity detection sensor, alarm indicator. .

The photovoltaic power generation equipment (F51, 52) is a renewable energy facility that generates and stores electricity using solar light and supplies it to the switchgear, and includes a solar generator and a storage battery. And renewable energy facilities may include wind power generation facilities, geothermal power generation facilities.

And each kind of building equipment (F) as described above are installed in each floor or partition space, or in a large building, such as apartment building is installed by each building.

The control center (C.C) is a device for comprehensively monitoring, controlling, and managing the situation of the entire building,

 A communication unit (c1) for communicating data by wire or wirelessly with the remote control panel (P) provided in the building facility (F),

A computer (c2) for controlling and managing the air control system (C.C), analyzing the data transmitted from the remote control panel (P), and issuing a command on whether the building equipment (F) is operated according to the data analysis result;

A monitor (c3) for allowing a manager to monitor the situation of the building equipment (F),

Information on building equipment (F) and remote control panel (P), information on how to respond to each situation, and data transmitted and received from the remote control panel (P), analyzed data information, and system operation And a database c4 in which the back is stored.

In addition, the central control unit CC may further include an Ethernet unit, an alarm unit, an SMSQN, a UPS unit and the like provided in the remote control panel P to be described below.

The central control unit (CC) analyzes the operation status information of the field devices of the building equipment (F) transmitted by the remote control panel (P) and the information detected by the various sensors to maintain the optimal environment in the building, If a problem occurs in the building equipment (F), the operation of the field devices is controlled according to the cause of the problem.

For example, if the temperature inside the building is high, turn on the air conditioner to lower the temperature.If the humidity is high, turn on the dehumidifier to lower the humidity.If the air contains a lot of fine dust, run the fan to purify the air,

If the room is dark, turn on the luminaire.

In particular, by analyzing the information transmitted from the remote control panel provided in the power equipment, when the power consumption of the building exceeds the reference peak power, the power supply to the electrical devices according to the priority stored and stored in the database is cut off To save energy,

Analyze the information transmitted from the remote control panel provided in the disaster prevention equipment, and in the event of a fire, stop the operation of the building equipment (except the disaster prevention equipment) installed in the fire occurrence zone, and register it in the database if an earthquake occurs. Stop operation of high-pressure or high-temperature field devices with high stored hazards to prevent secondary damage, and activate safety facilities (eg, fire extinguishers, flue smoke, alarms) in response to disasters.

The Direct Digit Control (DDC) is provided in each building facility (F), transmits and receives with the field devices constituting the building facility, controls the operation of the field device, and status information of the field devices. Collect and analyze them and transmit them to the central control unit (CC).

First, as shown in Figure 3, the remote control panel (P) is provided with an enclosure (1) to protect against accidental external shocks, dust, unauthorized access.

The door 2 is mounted at the front of the enclosure 1, and various equipment constituting the remote control panel is mounted inside the enclosure.

In addition, an outside air inlet 3 is formed at the lower right side of the enclosure, and an intake fan 4 is provided at the inside of the enclosure adjacent to the inlet 3, and an air outlet 5 is formed at the upper right side of the enclosure 5. Inside the enclosure adjacent to the exhaust plate 6 is provided.

A filter (not shown) is disposed at the inlet 3 to remove fine dust from the outside air, and a temperature sensor S1, a humidity sensor S2, and a dust sensor S3 are mounted inside the enclosure.

The temperature sensor, the humidity sensor, and the dust sensor respectively transmit the detected signals to the microcomputer 30, and the microcomputer 30 operates the intake fan and the exhaust plate by comparing the transmitted detection signal with a preset reference value. Adjust the temperature, humidity and dust density inside. For reference, when it is difficult to control the humidity with only the exhaust fan, it is preferable to further provide a dehumidifier.

As such, by providing various sensors and fans, the environment inside the enclosure of the remote control panel P does not adversely affect the components of the remote control panel so that the remote control panel can be stably operated without errors or malfunctions. do.

Next, as shown in the remote control panel (P) according to the present invention is

Microcomputer 30, communication unit 10, input / output unit 20, operation unit 50, memory 60, drive power supply unit 40, overvoltage breaker 200, UPS 70, Ethernet unit 81, SMS unit 85, download port 87 and the like.

The microcomputer 30 controls and manages the circle control panel P according to the present invention as a whole. The control and management method of the microcomputer 30 will be described together with each component described below.

The communication unit 10 communicates with a central control unit (C.C) that manages and controls the building facilities (F; Facilites) of the entire building to transmit and receive data.

The communication unit 10 includes a wired communication unit 11 that communicates with the central control unit C.C by wire, and a wireless communication unit 100 that communicates wirelessly.

Normally communicates with the central control device through a wired communication unit 11 via a wired line, and when a failure occurs in wired communication, the control is controlled by the microcomputer 10 to perform wireless communication through the wireless communication unit 100. .

In this case, it is preferable to provide a wired line for supporting wired communication through the wired communication unit 11 as a double line, so that a wired communication is possible through another wired line even if a problem occurs in any wired line.

In addition, when both wired lines fail and the wired communication is not performed, wireless communication through the wireless communication unit 100 is supported. Details of the wireless communication unit will be described later.

And the transmission data of the central control unit (CC) input through the communication unit 10 is input to the microcomputer 10, the microcomputer 10 controls the field devices in accordance with the input transmission data. And the communication unit 10 transmits the information collected and analyzed from the field devices to the central control unit (CC) through the communication unit 10.

The input / output unit 20 exchanges data with field devices constituting the building facilities (F). That is, the operation of the field devices by transmitting the operation signal to the field devices, and receives a variety of information about the operation status from the field devices.

For reference, the building equipment (F) has a variety of building equipment, such as power equipment, lighting equipment, air conditioning equipment, disaster prevention equipment, sanitary equipment, heating and cooling equipment, each building equipment is composed of a variety of field equipment.

For example, air conditioning equipment includes field equipment such as air conditioners, air flow units, fan coil units, convectors, radiators, air conditioners, and ventilation fans, and air conditioning equipment includes boilers, internal motors, cooling towers, heat exchangers, and ice storage equipment. Field devices are included.

And the remote control panel (P) is provided in each building equipment (F), each building equipment is also generally provided with a plurality of remote control panel. That is, there are many that includes a main remote control panel for controlling a specific building equipment as a whole, and a plurality of sub-remote control panel for controlling the field equipment of the building equipment provided in each spatially partitioned area and communicate with the remote control panel.

The signal of the data input and output through the input / output unit 20 is composed of four types. That is, there are four signals, analog input AI, analog output AO, digital input DI, and digital output DO. This is because each of the field devices operates with an analog or digital signal and outputs information as an analog or digital signal in the operating state.

The remote control panel (P) of the present invention operates as a digital signal in accordance with the digital era, but since the input and output data with digital or analog signals with the field devices, the analog signal of the data signal input to the input / output unit 20 is digital An A / D converter 23 for converting into a signal and a D / A converter 21 for converting and outputting a digital signal into an analog signal are provided.

The microcomputer 30 analyzes the data transmitted by the field devices input through the input / output unit 20, stores the data in the memory 60, and generates data to control the field devices through the input / output unit 20. send.

The operation unit 50 is for operation of a user, that is, an administrator, and includes a keypad 51 for receiving a command signal, and a display unit 53 for displaying information on an operation state of the keypad and operation states of field devices. It is done by

The user's command signal input through the operation unit 50 is input to the microcomputer 30, and the microcomputer 30 controls the field devices according to the input command signal or updates reference setting values for controlling the field devices. Or send and receive data with the central control unit (CC).

The memory 60 includes information on field devices to be controlled and managed by the remote control panel (P), various reference setting values required for control and management of each field device, information transmitted from the field devices, and information analyzed therefrom, It stores data information transmitted and received with the central control unit (CC) and various operation programs necessary for operating the remote control panel (P).

The driving power supply unit 40 converts the power input from the outside through the power line to the driving power to supply the components to the remote control panel P including the microcomputer 30 and the driving power.

For reference, the external power input through the power line may be a commercial AC power of 220V, or may be AC power stepped down to 24V through a power converter. In some cases, it may be a DC power source instead of an AC power source.

The Ethernet unit 81 supports remote control by accessing from an external remote place through the Internet network. The manager may be remotely connected through the Ethernet unit 81 to monitor the operation of the building equipment (F) through the remote control panel, and to perform remote control. Of course, for this purpose, a server supporting remote monitoring and remote control on the Internet should be provided.

The SMS unit 85 sends a short message (SMS) to a mobile phone of an administrator registered in the memory 60 when a problem occurs in a remote control panel P or a field device managed and controlled by the remote control panel. It supports notifying using service.

The microcomputer 30 may be in the vicinity of the remote control panel, or when there is a problem in the field devices managed and controlled by the remote control panel to issue an alarm through an alarm unit 83 including a flashing lamp and / or a speaker. Notify this to the same time, at the same time through the communication unit 10 transmits information on the occurrence of the problem to the central control unit (CC), and informs the administrator registered through the SMS unit (85).

The download port 87 supports the download of a program for upgrading an operating program stored in the memory 60, and the microcomputer (M) to match the type of building equipment (P) to be managed and controlled by the remote control panel (P). 30) is supported.

The overvoltage breaker 200 is connected to the input side of the driving power supply unit 40, and cuts a surge and an overvoltage from an external power source input through a power line to input the driving voltage supply unit 40 to the driving power supply unit 40. 40, as well as the microcomputer 30 connected thereto is protected from surge and overvoltage.

The unpowered power supply (UPS) 70, that is, the uninterruptible power supply supplies power to the driving power supply unit 40 when the supply of external power through the power line is cut off due to a power failure or the like for a predetermined time or more. Allow the remote control panel P to be driven.

The UPS 70 includes a battery B for discharging and supplying power charged to the driving power supply 40, and a charging module 300 for charging the battery.

In the present invention, the charge power capacity of the battery that can be supplied by the battery B of the UPS 70 supports a capacity that can be operated for about 90 days with the driving of the remote control panel P minimized. That is, various programs and information stored in the memory 60 have a charging power capacity that is not damaged for about 90 days even if no external power is supplied.

Hereinafter, the overvoltage breaker 200, the wireless communication unit 100, and the charging module 300 will be described in detail with reference to FIGS. 4 to 6.

For reference, in describing the overvoltage breaker 200 and the wireless communication unit 100 with reference to FIGS. 4 and 5, the same reference numerals are used for the electronic devices, but the overvoltage breaker 2010 and the wireless communication unit ( 100 will be described in sequence, and the description of the other components will be omitted in describing each of them, even if the reference numerals of the electronic elements are the same, there will be no confusion.

4 shows a circuit diagram of the overvoltage breaker 200.

For reference, the external power input through the power line is not excluded from the DC power, but in the present invention, since the commercial AC power or 24V AC power is used as the external power, the following description will be given using the external power as commercial AC power. do.

As shown in Figure 4, the overvoltage breaker 200 according to the present invention is

A surge blocking unit 210 for absorbing and blocking a surge of an input commercial AC power source,

A noise removing unit 220 for removing noise of commercial AC power passing through the surge blocking unit;

A switching unit 230 provided at an output terminal and supplying or blocking commercial AC power passing through the noise removing unit to the driving power supply unit 40 by an on / off switching operation;

A detection unit 240 for detecting the strength of the AC power output from the noise removing unit;

A control unit 250 which receives the detection signal of the detection unit and controls an on / off switching operation of the switching unit to cut off the overvoltage;

A counter electromotive force blocking unit 270 for blocking back electromotive force introduced from the driving power supply unit 40 through the switching unit;

And a starting power supply unit 260 for rectifying and smoothing the output AC power of the noise removing unit to supply the starting power to the switching unit.

The surge blocking unit 210 is connected in parallel to the input terminal, and comprises a varistor (MOV1) and the arrester (A1) connected in series with each other.

A fuse F1 is connected to an input side of the surge interrupter 210 to block an overcurrent when a commercial AC power is applied.

The varistor MOV1 operates as if it is open (OFF) with a high resistance value below a specific voltage, but operates as if it is shorted because the resistance value is lowered above a specific voltage. Thus, when a surge overvoltage is input to the input terminal, it is turned on so that a current can flow.

The arrester A1 absorbs and blocks a current corresponding to a surge overvoltage introduced by the varistor MOV1 turned on. More specifically, the input current is avoided to ground so that the surge overvoltage component of the commercial AC power supply is no longer transmitted to the rear side.

The noise removing unit 220 is connected in parallel with a line filter LF1, capacitors C1 and C2 connected in parallel to both sides of the line filter LF1, and an output side of the line filter LF1. The point comprises a pair of capacitors C3 and C4 with ground FG.

The line filter LF1 is composed of two coils wound in opposite directions, and cancels noise of the in-phase component from each other and serves as a low pass filter that blocks high frequency components.

Capacitors C1 and C2 connected in parallel to both sides of the line filter LF1 allow the line filter LF1 to remove noise in a wider band.

A pair of capacitors C3 and C4 connected in parallel to the output side of the line filter LF1, more specifically, the capacitor C2 provided on the output side of the line filter LF1, has an intermediate point grounded thereto. Eliminates electromagnetic noise caused by the AC characteristics of commercial AC power supplies.

That is, the pair of capacitors C3 and C4 remove conduction noise, enhance EMC (electromagnetic compatibility), lower EMI (electromagnetic interference) by about 10 dB, and resist EMS (electromagnetic immunity) by more than 10 kV. Have it.

The switching unit 230 is provided at the output terminal of the overvoltage circuit breaker, and is turned on and off by a switching operation to turn off when the commercial AC power is an overvoltage higher than a predetermined voltage so that the overvoltage is not supplied to the driving power supply unit 40.

In the present invention, when the commercial AC power exceeds AC 380V, the switching unit 230 is turned off to cut off.

In the present invention, although the relay is used as the switching unit 230, a transistor capable of switching operation, a thyristor, a triac, and the like may be used as the switching unit.

As the switching unit 230, the relay includes a driving coil RC and a magnet switch RS turned on and off by an electromagnetic force of the driving coil RC.

The detector 240 includes a current transformer CT1, a bridge diode BD1, a capacitor C8, and a resistor R9.

The current transformer CT1 induces a current flowing in the primary coil provided in the output line to the secondary coil according to the turns ratio, and detects the strength of the AC power output from the noise removing unit 220.

The bridge diode BD1 rectifies the power supplied to the secondary coil of the current transformer CT1. A capacitor C7 is connected between the current transformer CT1 and the bridge diode BD1 to smooth the AC power induced in the secondary coil of the current transformer CT1.

The capacitor C8 connected to the output of the bridge diode BD1 smoothes and directs the power rectified by the bridge diode BD1.

The resistor R9 connected to the output side of the capacitor C8 transfers the power DC-directed by the capacitor C8 to the controller.

The controller 250 includes a zener diode ZD3, an S1 U1, a first transistor Q1, and a second transistor Q2.

The zener diode (ZD3) is a detection signal of the detector 240, which is transmitted through the resistor (R9), that is, the AC power output from the noise removing unit 220 is converted into a DC through the detector 240 When the supplied power becomes an overvoltage of a predetermined voltage (for example, AC 380V) or more, the power is turned on and transferred to the SR U1.

The SR U1 is triggered when the zener diode ZD3 is turned on and the power is input through the gate terminal, and is transmitted to the first transistor Q1. SLC (U1) is a silicon control rectifier (SCR) and is a semiconductor device with high reliability and stable operation.

The capacitor C9 and the resistor R3 connected to the gate terminal of the SR U1 smooth and stabilize the power transmitted by the zener diode ZD3, and input the same to the SR U1. It protects the SRC (U1) and increases the accuracy of the trigger action.

When the SR U1 is triggered, the first transistor Q1 is turned on by applying the output power of the sensing unit 240 to the gate terminal.

The resistors R4, R5, and R6 connected to the gate terminal side of the first transistor Q1 protect the first transistor and increase the stability of on-off operation.

When the first transistor Q1 is turned on, the second transistor Q2 is turned on by applying the output power of the first transistor to the gate terminal.

The resistors R7 and R8 connected to the gate terminal side of the second transistor Q2 and the diode D6 connected between the drain terminal and the source terminal protect the second transistor Q2 and perform on / off operation. Increase stability

When the second transistor Q2 is turned on, the starting power of the starting power supply unit 260 is supplied to the driving coil RC of the switching unit through the second transistor Q2, and thus the switching unit 230. Magnet switch (RS) is turned off to block the over-voltage commercial AC power supply to the driving power supply (40).

The back EMF blocker 270 blocks back EMF from flowing from the driving power supply 40 through the driving coil RC of the switching unit 230.

The back EMF blocking unit 270 includes two zener diodes ZD1 and ZD2 connected in series with the diode D5 and the varistor MOV2 connected in parallel to the driving coil RC.

The starting power supply unit 260 rectifies and smoothes the output AC power of the noise removing unit 220 to supply the starting power to the switching unit 230.

The starting power supply 260 is a bridge diode (D1 ~ D4) for rectifying the output AC power of the surge blocking unit 220, and the capacitor (C5) for smoothing the rectified power from the bridge diode (D1 ~ D4) , C6, and resistors R1 and R2 for applying the starting power smoothed by the capacitors C5 and C6 to the switching unit 33.

5, a, b, and c show a detailed circuit diagram of the wireless communication unit 100. Referring to FIG.

As shown in FIG. 5, the wireless communication unit 100 includes an antenna ANT, a low pass filter 110, a reception data processing unit 120, a transmission data processing unit 130, a phase synchronization unit U5, and a transmission / reception selection switch ( U6), the power supply unit 140, and the CPU (U4).

The antenna ANT receives the received data from the central control device CC and transmits the transmission data received from the microcomputer 30 to the central control device CC.

The low pass filter 110 filters the received data received through the antenna ANT and the transmission data transmitted through the antenna ANT. That is, the low pass filter 110 blocks and removes a signal of a high frequency band from a signal (data) received or transmitted for transmission and reception, and passes a signal of a low frequency band.

As shown in the figure, the low pass filter 110 includes a resistor R24, two inductors L10 and L11, and two capacitors C34 and C68.

The receiving data processor 120 processes the received data received through the low pass filter 110 and transmits the received data to the phase synchronizer U5.

The received data processor 120 is connected to the front and rear of each of the first band pass filter CF2, the second band pass filter CF1, and the first and second band pass filters CF1 and CF2, and is configured as an input side for wireless communication. A first impedance matching unit 121 and a second impedance matching unit 122 that match the impedance of the output side with the output side, and a second impedance matching unit 122 of the second band pass filter CF1. And a noise amplifier Q6 that amplifies low frequency band noise of the received data passing through the band pass filter CF2.

The first and second band pass filters CF1 and CF2 pass a frequency signal of a specific band region among the low frequency bands passing through the low pass filter 110, and block high and low frequency signals of a band outside the specific band. The first and second impedance matching units 121 and 122 match the impedances before and after the first and second band pass filters CF1 and CF2, respectively, to prevent reflection loss and distortion of the RF signal, and the noise The amplifier Q6 amplifies the noise component included in the received data signal passing through the first band pass filter CF2 so that the noise is more efficiently removed from the second band pass filter CF1.

The transmission data processing unit 130 processes the transmission data transmitted by the phase synchronization unit U5 and outputs the data to the low pass filter 110 to transmit the transmission data to the central control apparatus 1 through the antenna ANT. do.

The transmission data processor 130 includes a power amplifier Q4 for amplifying a transmission data signal, a third impedance matching unit 131 connected to the front and rear of the power amplifier Q4 and matching impedances of both sides; And an all-pass filter 132 that filters and removes noise included in the transmission data signal passing through the power amplifier Q4 and inputs the noise to the low pass filter 110.

The power amplifier Q4 amplifies the transmission data signal so as not to be lost in the wireless communication process through the antenna ANT, and matches impedances of the input side and the output side of the third impedance matching unit 131 to the RF signal. It prevents reflection loss and distortion, and the all-pass filter 132 removes noise introduced into the transmission data signal in all frequency bands of the transmission data passing through the power amplifier Q4 without any frequency band blocking. High quality transmission data without distortion is transmitted wirelessly.

The transmission / reception selection switch U6 connects the low pass filter 110 and the reception data processing unit 120 or the transmission data processing unit 130, and the low pass filter 110 and the reception data in the process of receiving data. The processor 120 is connected, and in the transmission process, the low pass filter 110 and the transmission data processor 130 are connected.

The transmission / reception selection switch U6 is switched to the reception data processing unit 120 or the transmission data processing unit 130 by the operation of the two power transistors Q3 and Q5. The two power transistors Q3 and Q5 are controlled by the phase synchronization unit U5.

The phase lock unit U5 (PLL; Phase Lock Loop) synchronizes a signal phase of the received data inputted from the received data processor 120 with the received data outputted to the transmitted data processor 130 and the transmitted data. . That is, the frequency (phase) of data transmitted and received for wireless communication is synchronized to a frequency of a specific band.

The phase synchronizer Q5 is connected to an oscillator 101 for generating a clock signal for phase synchronization between the received data and the transmitted data signal, and a PLL filter 102 for preventing noise from being introduced during the phase synchronization process. .

As shown in FIG. 5B, the power supply unit 140 includes a driving power unit 141 for generating and supplying driving power for driving the communication unit 100, and a communication power unit 142 for generating and supplying communication power for wireless communication. )

The driving power supply unit 141 includes a first regulator U1 for constant voltage supplying power input from the outside through the interface ports J2 and J3, and a plurality of smoothing input power sources provided at an input side of the first regulator U1. Capacitors C2, C3 and C7, and a plurality of capacitors C4, C5 and C6 provided on the output side of the first regulator U1 to generate a smooth driving power for the output power. In the present invention, the driving power supply unit 141 generates and supplies driving power with a constant voltage of 5V.

The communication power unit 142 may include a second regulator U3 for stepping down and outputting the output power of the driving power unit 141 and a noise removing unit for smoothing the output power of the second regulator U3 and removing noise. 143. The noise removing unit 143 includes a plurality of capacitors C8, C9, C10, and C11 and an inductor L1.

In the interface ports J2 and J3 shown in FIG. 5B, the transmission level matching transistor Q1 adjusts the level of transmission data transmitted from the microcomputer to a level (3V in the drawing) that the wireless communication unit 100 can process. And reception level matching transistors Q2 and Q7 for adjusting the level of the received data transmitted from the CPU U4 or the phase synchronization unit U5 to a level (5V in the drawing) that the microcomputer 30 can process. It is.

The CPU U4 controls the wireless communication unit 100 as a whole.

The CPU U4 has a download port J5 for downloading various programs for controlling the wireless communication unit 100 as shown in FIG. 5C, and a signal for controlling and communicating with the wireless communication unit 100. The clock unit 103 or the like for generating the clock signal is connected.

For reference, the CPU U4 transmits and receives data and transmission data with pin 8 of the phase synchronization unit U5 through pin 22, and transmits the received data to the microcomputer 30 through pin 25. , Through the pin 24 receives the transmission data from the microcomputer (30).

Hereinafter, the charging module 300 according to the present invention will be described in more detail with reference to FIG. 6.

As shown in FIG. 5, the charging module 300 according to the present invention includes a transformer 310, a charging unit 320, a charging switch unit 330, a switch driver 340, an amplifier 360, and an overload detection unit 370. In addition, the charge voltage detection unit 380, the full capacity determination unit 390, the output terminal 350, and the protection fuses F1 and F2 provided at the input terminal and the output terminal, and the detection resistor RS for detecting the charging power supplied to the battery. )

The transformer 310 step-down (or step-up) the external power input through the power line.

The charging unit 320 rectifies the output power of the transformer to supply the charging power to the battery (B) connected to the output terminal 350 to charge.

The charging unit 320 includes a bridge diode for full-wave rectifying the input power, a capacitor and a resistor for smoothing and directing the rectified power.

The charging switch unit 330 connects the charging unit 320 and the output terminal 350, and turns on or off the charging line to supply or cut off the charging power of the charging unit 320 to the battery B.

The charging switch unit 330 uses a relay that is controlled on and off by the switch driver 340.

For reference, the charging switch unit 330 is turned off to open the charging line itself, even when the battery (B) is full, the charging power of the battery is discharged even if the external power is cut off when the charging line is connected to the charging module 300 Since it is used as standby power, the charging power line is opened to prevent this.

The switch driver 340 controls the on / off of the charging switch unit 330.

In other words, when the overload detection unit 370 detects the charging power applied to the battery B as an overload (overvoltage or overcurrent), the full capacity detection unit 390 indicates that the battery B is full. When it is determined, the charging switch unit 330 is turned off to block charging power from being applied to the battery.

The sensing resistor RS senses the charging power output from the charging unit, and the amplifying unit 360 amplifies the charging power detected by the sensing resistor RS and transmits the amplified charging power to the overload detection unit 370.

The overload detection unit 370 detects whether the charging power applied to the battery is an overload, that is, an overvoltage or an overcurrent, from the charging power transmitted from the amplifying unit 360, and transmits it to the switch driver 340 to damage the battery. To prevent.

The charging voltage detecting unit 380 detects the charging voltage charged in the battery, and transmits it to the full discrimination unit 390.

The full discrimination unit 390 determines whether the battery is fully charged from the charging voltage transmitted by the charging voltage detection unit 380, and transmits the result to the switch driver 340 to open the charging line. In addition, the microcomputer 30 is transmitted to the microcomputer 30 so that the manager can check the charging state of the battery through the operation unit 50.

In the above description of the present invention with reference to the accompanying drawings has been described for the energy-saving automatic control system having a stability composed of specific components, the present invention can be variously modified and changed by those skilled in the art, such variations and Changes should be construed as falling within the protection scope of the present invention.

F: Building Equipment
CC: Central Control Unit
c1: communication unit c2: computer
c3: monitor c4: database
P: remote control panel
10: communication unit 20: input / output unit
30: microcomputer 40: drive power supply
50: control panel 60: memory
70: UPS
100: wireless communication unit 200: overvoltage breaker
400: charging module

Claims (4)

Power equipment including distribution panel, distribution panel, electricity meter, and distributing the power supplied to the building to each electric device,
Including heater and air conditioner, temperature sensor, humidifier and humidity sensor, ventilator and dust sensor, air conditioning equipment to control temperature, humidity and ventilation in the building,
It includes a luminaire, an illuminance sensor, an entrance detection sensor, lighting equipment for controlling lighting in a building,
Building equipment including fire detectors, fire hydrants, earthquake detection sensors, and disaster prevention facilities for preventing disasters in buildings;

A remote control panel provided in each of the power equipment, the air conditioning equipment, the lighting equipment, and the disaster prevention equipment to control field devices constituting them;

In the building equipment automatic control system comprising a computer, a monitor and a database, the central control unit for communicating with the remote control panel, the monitoring and management of the situation of the building facilities;

The remote control panel
Communication unit for communicating with the central control device;
An input / output unit for inputting / outputting data with a field device;
An operation unit including a keypad and a display unit for a user operation;
A memory for storing input / output information with an operating program;
The communication unit, the input / output unit, the operation unit and the memory are connected to control them, and a microcomputer for analyzing the data of the field apparatus input from the input / output unit;

The central control device
Analyzing the information transmitted from the remote control panel provided in the power equipment, if the power consumption of the building exceeds the reference peak power, the power supply to the electrical devices are cut off according to the priority stored in the database to save energy Reduce costs,
Analyze the information transmitted from the remote control panel provided in the disaster prevention equipment, and in the event of a fire, stop the operation of the building equipment (except the disaster prevention equipment) installed in the fire occurrence zone, and register it in the database if an earthquake occurs. It is characterized in that the stability is increased by stopping the operation of the field device of high pressure or high temperature stored risk factors,

The communication unit of the remote control panel and the wired communication unit for communicating with the central control unit by wire;
In the case of a failure in the communication of the wired communication unit made of a wireless communication unit for wireless communication with the central control unit,

The wireless communication unit
An antenna for wirelessly transmitting and receiving data to and from the central control apparatus;
A low pass filter for filtering received data and transmitted data of the antenna;
A first impedance matching unit and a first impedance matching unit connected to the front and rear of the first band pass filter and the second band pass filter for filtering the received data passing through the low pass filter, respectively; A reception data processing unit including a second impedance matching unit, a noise amplifying unit amplifying low frequency band noise of the output received data of the first impedance matching unit, and inputting the low frequency band noise to the second impedance matching unit;
A power amplifier for amplifying the transmission data, a third impedance matching unit connected to the front and rear of the power amplifier, and an all-pass filter for removing noise of the output data of the third impedance matching unit and filtering the output data into the low pass filter; A transmission data processing unit,
A phase synchronization unit for synchronizing the signal phase of the reception data inputted from the reception data processing unit with the transmission data outputted to the transmission data processing unit;
A transmission / reception selection switch connecting the low pass filter to the reception data processor or the transmission data processor;
A power supply unit including a driving power unit for generating a driving power required for driving the communication unit by converting the external input power into a constant voltage, and a communication power unit for generating a communication power for wireless communication by constant voltage output power of the driving power unit;
And an CPU for relaying transmission and reception of the reception data and the transmission data between the phase synchronization unit and the microcomputer and controlling the communication unit. The method of claim 1,
Including a solar power generator, a storage battery, the solar power generation equipment for supplying power storage power to the switchgear of the power equipment;

The remote control panel
Enclosure to protect the components built-in,
Outside air inlet and bet outlet formed in the lower and upper portions of the enclosure,
A temperature sensor and a humidity sensor mounted inside the enclosure;
Further comprising an intake fan and an exhaust fan provided inside the enclosure adjacent to the inlet and outlet,
The microcomputer drives the intake fan and the exhaust fan according to the signals sensed by the temperature sensor and the humidity sensor, and maintains the temperature and humidity inside the enclosure to increase the stability. system. The method according to claim 1 or 2,
The remote control panel
A driving power supply unit converting power input through a power line into driving power and supplying the power to the microcomputer;
An overvoltage circuit breaker connected to an input side of the driving power supply and blocking a surge and an overvoltage of a power input through a power line;

The overvoltage breaker
Surge interruption part which absorbs the surge of the input power supply, and blocks it,
A noise removing unit for removing noise of the power supply passing through the surge blocking unit;
A switching unit which is provided at an output terminal and supplies or cuts off the power passing through the noise removing unit by an on / off switching operation to the driving power supply unit;
A detector for detecting the intensity of the power output from the noise removing unit;
A control unit which receives the detection signal of the detection unit and controls an on / off switching operation of the switching unit to cut off the overvoltage;
A counter electromotive force blocking unit to block back electromotive force introduced from the driving power supply unit through the switching unit;
Rectification and smoothing the output power of the noise removing unit; a starting power supply for supplying the starting power to the switching unit; energy saving type automatic control system having a stability comprising a. delete

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